コード例 #1
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 def test_1(self):
     # This tests for a refcounting bug in the swig wrappers
     # that was previously problematic.
     # See https://github.com/pandegroup/openmm/issues/1214
     for cycle in range(10):
         system = mm.System()
         system.getDefaultPeriodicBoxVectors()
コード例 #2
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def testForce(model_file, output_forces):

    # Create a random cloud of particles.
    numParticles = 10
    system = mm.System()
    positions = np.random.rand(numParticles, 3)
    for i in range(numParticles):
        system.addParticle(1.0)

    # Create a force
    force = ot.TorchForce(model_file)
    assert not force.getOutputsForces()  # Check the default
    force.setOutputsForces(output_forces)
    assert force.getOutputsForces() == output_forces
    system.addForce(force)

    # Compute the forces and energy.
    integ = mm.VerletIntegrator(1.0)
    context = mm.Context(system, integ,
                         mm.Platform.getPlatformByName('Reference'))
    context.setPositions(positions)
    state = context.getState(getEnergy=True, getForces=True)

    # See if the energy and forces are correct.  The network defines a potential of the form E(r) = |r|^2
    expectedEnergy = np.sum(positions * positions)
    assert np.allclose(
        expectedEnergy,
        state.getPotentialEnergy().value_in_unit(unit.kilojoules_per_mole))
    assert np.allclose(-2 * positions, state.getForces(asNumpy=True))
コード例 #3
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def make_toy_system_object(model):
    """
    Make openmm system and topology files for use with a toy system.
    """
    system = openmm.System()
    topology = openmm_app.Topology()
    num_particles = model.toy_settings.num_particles
    assert model.toy_settings.num_particles == len(model.toy_settings.masses)
    new_expression = "k*(" + model.toy_settings.potential_energy_expression + ")"
    force = openmm.CustomCentroidBondForce(num_particles, new_expression)
    force.addGlobalParameter("k", 1.0 * openmm.unit.kilocalories_per_mole)
    groups_list = []
    for i in range(num_particles):
        mass = model.toy_settings.masses[i] * openmm.unit.amu
        system.addParticle(mass)
        atom_name = "X{}".format(i)
        if not atom_name in openmm_app.element.Element._elements_by_symbol:
            element = openmm_app.element.Element(0, atom_name, atom_name, mass)
        else:
            element = openmm_app.element.Element._elements_by_symbol[atom_name]
        chain = topology.addChain()
        residue = topology.addResidue("UNK", chain)
        topology.addAtom(atom_name, element, residue)
        groups_list.append(force.addGroup([i]))

    force.addBond(groups_list, [])
    system.addForce(force)
    return system, topology
コード例 #4
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ファイル: TestForceGroups.py プロジェクト: z-gong/openmm
    def setUp(self):
        system = mm.System()
        system.addParticle(1.0)

        for i in range(32):
            force = mm.CustomExternalForce(str(i))
            force.addParticle(0, [])
            force.setForceGroup(i)
            system.addForce(force)

        platform = mm.Platform.getPlatformByName('Reference')
        context = mm.Context(system, mm.VerletIntegrator(0), platform)
        context.setPositions([(0, 0, 0)])
        self.context = context
コード例 #5
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def testModuleArguments(deviceString, precision):

    if pt.cuda.device_count() < 1 and deviceString == 'cuda:0':
        pytest.skip('A CUDA device is not available')
    if pt.cuda.device_count() < 2 and deviceString == 'cuda:1':
        pytest.skip('Two CUDA devices are not available')

    class TestModule(pt.nn.Module):
        def __init__(self, device, dtype, positions):
            super().__init__()
            self.device = device
            self.dtype = dtype
            self.register_buffer('positions', pt.tensor(positions).to(dtype))

        def forward(self, positions):
            assert self.positions.device == self.device
            assert positions.device == self.device
            assert positions.dtype == self.dtype
            assert pt.all(positions == self.positions)
            return pt.sum(positions)

    with NamedTemporaryFile() as fd:

        numParticles = 10
        system = mm.System()
        positions = np.random.rand(numParticles, 3)
        for _ in range(numParticles):
            system.addParticle(1.0)

        device = pt.device(deviceString)
        if device.type == 'cpu' or precision == 'double':
            dtype = pt.float64
        else:
            dtype = pt.float32
        module = TestModule(device, dtype, positions)
        pt.jit.script(module).save(fd.name)
        force = ot.TorchForce(fd.name)
        system.addForce(force)

        integrator = mm.VerletIntegrator(1.0)
        platform = mm.Platform.getPlatformByName(device.type.upper())
        properties = {}
        if device.type == 'cuda':
            properties['DeviceIndex'] = str(device.index)
            properties['Precision'] = precision
        context = mm.Context(system, integrator, platform, properties)

        context.setPositions(positions)
        context.getState(getEnergy=True, getForces=True)
コード例 #6
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ファイル: TestBytes.py プロジェクト: z-gong/openmm
    def test_createCheckpoint(self):
        system = mm.System()
        system.addParticle(1.0)
        refPositions = [(0,0,0)]

        platform = mm.Platform.getPlatformByName('Reference')
        context = mm.Context(system, mm.VerletIntegrator(0), platform)
        context.setPositions(refPositions)
        chk = context.createCheckpoint()
        # check that the return value of createCheckpoint is of type bytes (non-unicode)
        assert isinstance(chk, bytes)

        # set the positions to something random then reload the checkpoint, and
        # make sure that the positions get restored correctly
        context.setPositions([(12345, 12345, 123451)])
        context.loadCheckpoint(chk)
        newPositions = context.getState(getPositions=True).getPositions()._value

        assert newPositions == refPositions
コード例 #7
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ファイル: mlpotential.py プロジェクト: peastman/openmm-ml
    def createSystem(self, topology: openmm.app.Topology, **args) -> openmm.System:
        """Create a System for running a simulation with this potential function.

        Parameters
        ----------
        topology: Topology
            the Topology for which to create a System
        args:
            particular potential functions may define additional arguments that can
            be used to customize them.  See the documentation on the specific
            potential functions for more information.

        Returns
        -------
        a newly created System object that uses this potential function to model the Topology
        """
        system = openmm.System()
        for atom in topology.atoms():
            if atom.element is None:
                system.addParticle(0)
            else:
                system.addParticle(atom.element.mass)
        self._impl.addForces(topology, system, None, 0, **args)
        return system
コード例 #8
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ファイル: desmonddmsfile.py プロジェクト: z-gong/openmm
    def createSystem(self,
                     nonbondedMethod=ff.NoCutoff,
                     nonbondedCutoff=1.0 * nanometer,
                     ewaldErrorTolerance=0.0005,
                     removeCMMotion=True,
                     hydrogenMass=None,
                     OPLS=False,
                     implicitSolvent=None,
                     AGBNPVersion=1):
        """Construct an OpenMM System representing the topology described by this
        DMS file

        Parameters
        ----------
        nonbondedMethod : object=NoCutoff
            The method to use for nonbonded interactions.  Allowed values are
            NoCutoff, CutoffNonPeriodic, CutoffPeriodic, Ewald, PME, or LJPME.
        nonbondedCutoff : distance=1*nanometer
            The cutoff distance to use for nonbonded interactions
        ewaldErrorTolerance : float=0.0005
            The error tolerance to use if nonbondedMethod is Ewald, PME, or LJPME.
        removeCMMotion : boolean=True
            If true, a CMMotionRemover will be added to the System
        hydrogenMass : mass=None
            The mass to use for hydrogen atoms bound to heavy atoms.  Any mass
            added to a hydrogen is subtracted from the heavy atom to keep their
            total mass the same.
        OPLS : boolean=False
            If True, forces OPLS combining rules
        implicitSolvent: string=None
            If not None, creates implicit solvent force of the given name
            Allowed values are: HCT and 'AGBNP'
            (the corresponding tables must be present in the DMS file)
        AGBNPVersion: int=1
            AGBNP implicit solvent version
        """
        self._checkForUnsupportedTerms()
        sys = mm.System()

        # Build the box dimensions
        boxSize = self.topology.getUnitCellDimensions()
        if boxSize is not None:
            sys.setDefaultPeriodicBoxVectors(
                (boxSize[0], 0, 0), (0, boxSize[1], 0), (0, 0, boxSize[2]))
        elif nonbondedMethod in (ff.CutoffPeriodic, ff.Ewald, ff.PME,
                                 ff.LJPME):
            raise ValueError(
                'Illegal nonbonded method for a non-periodic system')

        # Create all of the particles
        for (fcounter, conn, tables, offset) in self._localVars():
            for mass in conn.execute('SELECT mass FROM particle ORDER BY id'):
                sys.addParticle(mass[0] * dalton)

        # Add all of the forces
        self._addBondsToSystem(sys)
        self._addAnglesToSystem(sys)
        self._addConstraintsToSystem(sys)
        self._addPeriodicTorsionsToSystem(sys, OPLS)
        self._addImproperHarmonicTorsionsToSystem(sys)
        self._addCMAPToSystem(sys)
        self._addVirtualSitesToSystem(sys)
        self._addPositionalHarmonicRestraints(sys)
        nb, cnb = self._addNonbondedForceToSystem(sys, OPLS)

        # Finish configuring the NonbondedForce.
        methodMap = {
            ff.NoCutoff: mm.NonbondedForce.NoCutoff,
            ff.CutoffNonPeriodic: mm.NonbondedForce.CutoffNonPeriodic,
            ff.CutoffPeriodic: mm.NonbondedForce.CutoffPeriodic,
            ff.Ewald: mm.NonbondedForce.Ewald,
            ff.PME: mm.NonbondedForce.PME,
            ff.LJPME: mm.NonbondedForce.LJPME
        }
        nb.setNonbondedMethod(methodMap[nonbondedMethod])
        nb.setCutoffDistance(nonbondedCutoff)
        nb.setEwaldErrorTolerance(ewaldErrorTolerance)
        if cnb is not None:
            nb.setUseDispersionCorrection(False)
            if nonbondedMethod in (ff.CutoffPeriodic, ff.Ewald, ff.PME,
                                   ff.LJPME):
                cnb.setNonbondedMethod(methodMap[ff.CutoffPeriodic])
                cnb.setCutoffDistance(nonbondedCutoff)
            elif nonbondedMethod == ff.CutoffNonPeriodic:
                cnb.setNonbondedMethod(methodMap[ff.CutoffNonPeriodic])
                cnb.setCutoffDistance(nonbondedCutoff)
            else:
                cnb.setNonbondedMethod(methodMap[ff.NoCutoff])
            cnb.setUseSwitchingFunction(False)
            cnb.setUseLongRangeCorrection(False)

        #add implicit solvent model.
        if implicitSolvent is not None:

            if not (implicitSolvent in (HCT, 'AGBNP', 'GVolSA', 'AGBNP3')):
                raise ValueError('Illegal implicit solvent method')

            if self._verbose:
                print('Adding implicit solvent ...')

            #with implicit solvent turn off native reaction field
            #However note that this does not affect the shifted Coulomb potential of the Nonbonded force
            #(it affects the only the energy, not the forces and equation of motion)
            nb.setReactionFieldDielectric(1.0)

            if implicitSolvent is HCT:
                gb_parms = self._get_gb_params()

                if gb_parms:
                    if self._verbose:
                        print('Adding HCT GB force ...')
                    gb = GBSAHCTForce(SA='ACE')
                    for i in range(len(gb_parms)):
                        gb.addParticle(list(gb_parms[i]))
                    gb.finalize()
                    sys.addForce(gb)
                else:
                    raise IOError("No HCT parameters found in DMS file")

            if implicitSolvent == 'AGBNP3':
                #load AGBNP3 plugin if available
                try:
                    from AGBNP3plugin import AGBNP3Force
                except ImportError:
                    raise NotImplementedError(
                        'AGBNP3 is not supported in this version')
                #sets up AGBNP3
                gb_parms = self._get_agbnp2_params()
                if gb_parms:
                    if self._verbose:
                        print('Adding AGBNP3 force ...')
                    gb = AGBNP3Force()
                    # add particles
                    for i in range(len(gb_parms)):
                        p = gb_parms[i]
                        gb.addParticle(p[0], p[1], p[2], p[3], p[4], p[5],
                                       p[6])
                    # connection table (from bonds)
                    self._add_agbnp2_ct(gb)
                    sys.addForce(gb)
                else:
                    raise IOError("No AGBNP parameters found in DMS file")

            if implicitSolvent == 'GVolSA':
                #implemented as AGBNP version 0
                implicitSolvent = 'AGBNP'
                AGBNPVersion = 0
                if self._verbose:
                    print('Using GVolSA')

            if implicitSolvent == 'AGBNP':
                #load AGBNP plugin if available
                try:
                    from AGBNPplugin import AGBNPForce
                except ImportError:
                    raise NotImplementedError(
                        'AGBNP is not supported in this version')
                #sets up AGBNP
                gb_parms = self._get_agbnp2_params()
                if gb_parms:
                    gb = AGBNPForce()
                    gb.setNonbondedMethod(methodMap[nonbondedMethod])
                    gb.setCutoffDistance(nonbondedCutoff)
                    gb.setVersion(AGBNPVersion)
                    if self._verbose:
                        print('Using AGBNP force version %d ...' %
                              AGBNPVersion)
                    # add particles
                    for i in range(len(gb_parms)):
                        [
                            radiusN, chargeN, gammaN, alphaN, hbtype, hbwN,
                            ishydrogenN
                        ] = gb_parms[i]
                        h_flag = ishydrogenN > 0
                        gb.addParticle(radiusN, gammaN, alphaN, chargeN,
                                       h_flag)
                    sys.addForce(gb)
                    self.gb_parms = gb_parms
                    self.agbnp = gb
                else:
                    raise IOError("No AGBNP parameters found in DMS file")

        # Adjust masses.
        if hydrogenMass is not None:
            for atom1, atom2 in self.topology.bonds():

                if atom1.element == hydrogen:
                    (atom1, atom2) = (atom2, atom1)
                if atom2.element == hydrogen and atom1.element not in (
                        hydrogen, None):
                    transferMass = hydrogenMass - sys.getParticleMass(
                        atom2.index)
                    sys.setParticleMass(atom2.index, hydrogenMass)
                    sys.setParticleMass(
                        atom1.index,
                        sys.getParticleMass(atom1.index) - transferMass)

        # Add a CMMotionRemover.
        if removeCMMotion:
            sys.addForce(mm.CMMotionRemover())

        return sys
コード例 #9
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 def test_int64(self):
     indices = np.array([0, 1, 2])
     sys = mm.System()
     sys.addParticle(2.0)
     assert sys.getParticleMass(indices[0]) == 2.0 * unit.amu
コード例 #10
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ファイル: make.py プロジェクト: uibcdf/MolSysMT
    if os.path.isfile(filename):
        os.remove(filename)

# simulation

mass_1 = 39.948 * unit.amu
sigma_1 = 3.404 * unit.angstroms
epsilon_1 = 0.238 * unit.kilocalories_per_mole
charge_1 = 0.0 * unit.elementary_charge

mass_2 = 131.293 * unit.amu
sigma_2 = 3.961 * unit.angstroms
epsilon_2 = 0.459 * unit.kilocalories_per_mole
charge_2 = 0.0 * unit.elementary_charge

system = mm.System()

non_bonded_force = mm.NonbondedForce()

reduced_sigma = 0.5 * (sigma_1 + sigma_2)
cutoff_distance = 4.0 * reduced_sigma
switching_distance = 3.0 * reduced_sigma
non_bonded_force.setNonbondedMethod(mm.NonbondedForce.CutoffPeriodic)
non_bonded_force.setUseSwitchingFunction(True)
non_bonded_force.setCutoffDistance(cutoff_distance)
non_bonded_force.setSwitchingDistance(switching_distance)

system.addParticle(mass_1)
non_bonded_force.addParticle(charge_1, sigma_1, epsilon_1)

system.addParticle(mass_2)